599 lines
20 KiB
Plaintext
599 lines
20 KiB
Plaintext
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MARKING SHARED-MEMORY ACCESSES
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==============================
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This document provides guidelines for marking intentionally concurrent
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normal accesses to shared memory, that is "normal" as in accesses that do
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not use read-modify-write atomic operations. It also describes how to
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document these accesses, both with comments and with special assertions
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processed by the Kernel Concurrency Sanitizer (KCSAN). This discussion
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builds on an earlier LWN article [1].
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ACCESS-MARKING OPTIONS
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======================
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The Linux kernel provides the following access-marking options:
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1. Plain C-language accesses (unmarked), for example, "a = b;"
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2. Data-race marking, for example, "data_race(a = b);"
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3. READ_ONCE(), for example, "a = READ_ONCE(b);"
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The various forms of atomic_read() also fit in here.
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4. WRITE_ONCE(), for example, "WRITE_ONCE(a, b);"
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The various forms of atomic_set() also fit in here.
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These may be used in combination, as shown in this admittedly improbable
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example:
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WRITE_ONCE(a, b + data_race(c + d) + READ_ONCE(e));
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Neither plain C-language accesses nor data_race() (#1 and #2 above) place
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any sort of constraint on the compiler's choice of optimizations [2].
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In contrast, READ_ONCE() and WRITE_ONCE() (#3 and #4 above) restrict the
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compiler's use of code-motion and common-subexpression optimizations.
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Therefore, if a given access is involved in an intentional data race,
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using READ_ONCE() for loads and WRITE_ONCE() for stores is usually
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preferable to data_race(), which in turn is usually preferable to plain
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C-language accesses. It is permissible to combine #2 and #3, for example,
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data_race(READ_ONCE(a)), which will both restrict compiler optimizations
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and disable KCSAN diagnostics.
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KCSAN will complain about many types of data races involving plain
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C-language accesses, but marking all accesses involved in a given data
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race with one of data_race(), READ_ONCE(), or WRITE_ONCE(), will prevent
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KCSAN from complaining. Of course, lack of KCSAN complaints does not
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imply correct code. Therefore, please take a thoughtful approach
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when responding to KCSAN complaints. Churning the code base with
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ill-considered additions of data_race(), READ_ONCE(), and WRITE_ONCE()
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is unhelpful.
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In fact, the following sections describe situations where use of
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data_race() and even plain C-language accesses is preferable to
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READ_ONCE() and WRITE_ONCE().
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Use of the data_race() Macro
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----------------------------
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Here are some situations where data_race() should be used instead of
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READ_ONCE() and WRITE_ONCE():
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1. Data-racy loads from shared variables whose values are used only
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for diagnostic purposes.
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2. Data-racy reads whose values are checked against marked reload.
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3. Reads whose values feed into error-tolerant heuristics.
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4. Writes setting values that feed into error-tolerant heuristics.
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Data-Racy Reads for Approximate Diagnostics
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Approximate diagnostics include lockdep reports, monitoring/statistics
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(including /proc and /sys output), WARN*()/BUG*() checks whose return
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values are ignored, and other situations where reads from shared variables
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are not an integral part of the core concurrency design.
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In fact, use of data_race() instead READ_ONCE() for these diagnostic
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reads can enable better checking of the remaining accesses implementing
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the core concurrency design. For example, suppose that the core design
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prevents any non-diagnostic reads from shared variable x from running
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concurrently with updates to x. Then using plain C-language writes
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to x allows KCSAN to detect reads from x from within regions of code
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that fail to exclude the updates. In this case, it is important to use
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data_race() for the diagnostic reads because otherwise KCSAN would give
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false-positive warnings about these diagnostic reads.
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If it is necessary to both restrict compiler optimizations and disable
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KCSAN diagnostics, use both data_race() and READ_ONCE(), for example,
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data_race(READ_ONCE(a)).
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In theory, plain C-language loads can also be used for this use case.
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However, in practice this will have the disadvantage of causing KCSAN
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to generate false positives because KCSAN will have no way of knowing
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that the resulting data race was intentional.
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Data-Racy Reads That Are Checked Against Marked Reload
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The values from some reads are not implicitly trusted. They are instead
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fed into some operation that checks the full value against a later marked
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load from memory, which means that the occasional arbitrarily bogus value
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is not a problem. For example, if a bogus value is fed into cmpxchg(),
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all that happens is that this cmpxchg() fails, which normally results
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in a retry. Unless the race condition that resulted in the bogus value
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recurs, this retry will with high probability succeed, so no harm done.
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However, please keep in mind that a data_race() load feeding into
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a cmpxchg_relaxed() might still be subject to load fusing on some
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architectures. Therefore, it is best to capture the return value from
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the failing cmpxchg() for the next iteration of the loop, an approach
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that provides the compiler much less scope for mischievous optimizations.
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Capturing the return value from cmpxchg() also saves a memory reference
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in many cases.
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In theory, plain C-language loads can also be used for this use case.
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However, in practice this will have the disadvantage of causing KCSAN
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to generate false positives because KCSAN will have no way of knowing
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that the resulting data race was intentional.
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Reads Feeding Into Error-Tolerant Heuristics
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Values from some reads feed into heuristics that can tolerate occasional
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errors. Such reads can use data_race(), thus allowing KCSAN to focus on
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the other accesses to the relevant shared variables. But please note
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that data_race() loads are subject to load fusing, which can result in
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consistent errors, which in turn are quite capable of breaking heuristics.
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Therefore use of data_race() should be limited to cases where some other
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code (such as a barrier() call) will force the occasional reload.
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Note that this use case requires that the heuristic be able to handle
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any possible error. In contrast, if the heuristics might be fatally
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confused by one or more of the possible erroneous values, use READ_ONCE()
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instead of data_race().
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In theory, plain C-language loads can also be used for this use case.
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However, in practice this will have the disadvantage of causing KCSAN
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to generate false positives because KCSAN will have no way of knowing
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that the resulting data race was intentional.
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Writes Setting Values Feeding Into Error-Tolerant Heuristics
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The values read into error-tolerant heuristics come from somewhere,
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for example, from sysfs. This means that some code in sysfs writes
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to this same variable, and these writes can also use data_race().
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After all, if the heuristic can tolerate the occasional bogus value
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due to compiler-mangled reads, it can also tolerate the occasional
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compiler-mangled write, at least assuming that the proper value is in
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place once the write completes.
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Plain C-language stores can also be used for this use case. However,
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in kernels built with CONFIG_KCSAN_ASSUME_PLAIN_WRITES_ATOMIC=n, this
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will have the disadvantage of causing KCSAN to generate false positives
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because KCSAN will have no way of knowing that the resulting data race
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was intentional.
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Use of Plain C-Language Accesses
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--------------------------------
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Here are some example situations where plain C-language accesses should
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used instead of READ_ONCE(), WRITE_ONCE(), and data_race():
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1. Accesses protected by mutual exclusion, including strict locking
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and sequence locking.
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2. Initialization-time and cleanup-time accesses. This covers a
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wide variety of situations, including the uniprocessor phase of
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system boot, variables to be used by not-yet-spawned kthreads,
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structures not yet published to reference-counted or RCU-protected
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data structures, and the cleanup side of any of these situations.
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3. Per-CPU variables that are not accessed from other CPUs.
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4. Private per-task variables, including on-stack variables, some
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fields in the task_struct structure, and task-private heap data.
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5. Any other loads for which there is not supposed to be a concurrent
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store to that same variable.
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6. Any other stores for which there should be neither concurrent
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loads nor concurrent stores to that same variable.
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But note that KCSAN makes two explicit exceptions to this rule
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by default, refraining from flagging plain C-language stores:
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a. No matter what. You can override this default by building
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with CONFIG_KCSAN_ASSUME_PLAIN_WRITES_ATOMIC=n.
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b. When the store writes the value already contained in
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that variable. You can override this default by building
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with CONFIG_KCSAN_REPORT_VALUE_CHANGE_ONLY=n.
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c. When one of the stores is in an interrupt handler and
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the other in the interrupted code. You can override this
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default by building with CONFIG_KCSAN_INTERRUPT_WATCHER=y.
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Note that it is important to use plain C-language accesses in these cases,
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because doing otherwise prevents KCSAN from detecting violations of your
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code's synchronization rules.
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ACCESS-DOCUMENTATION OPTIONS
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============================
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It is important to comment marked accesses so that people reading your
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code, yourself included, are reminded of the synchronization design.
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However, it is even more important to comment plain C-language accesses
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that are intentionally involved in data races. Such comments are
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needed to remind people reading your code, again, yourself included,
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of how the compiler has been prevented from optimizing those accesses
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into concurrency bugs.
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It is also possible to tell KCSAN about your synchronization design.
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For example, ASSERT_EXCLUSIVE_ACCESS(foo) tells KCSAN that any
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concurrent access to variable foo by any other CPU is an error, even
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if that concurrent access is marked with READ_ONCE(). In addition,
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ASSERT_EXCLUSIVE_WRITER(foo) tells KCSAN that although it is OK for there
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to be concurrent reads from foo from other CPUs, it is an error for some
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other CPU to be concurrently writing to foo, even if that concurrent
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write is marked with data_race() or WRITE_ONCE().
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Note that although KCSAN will call out data races involving either
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ASSERT_EXCLUSIVE_ACCESS() or ASSERT_EXCLUSIVE_WRITER() on the one hand
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and data_race() writes on the other, KCSAN will not report the location
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of these data_race() writes.
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EXAMPLES
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========
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As noted earlier, the goal is to prevent the compiler from destroying
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your concurrent algorithm, to help the human reader, and to inform
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KCSAN of aspects of your concurrency design. This section looks at a
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few examples showing how this can be done.
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Lock Protection With Lockless Diagnostic Access
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-----------------------------------------------
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For example, suppose a shared variable "foo" is read only while a
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reader-writer spinlock is read-held, written only while that same
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spinlock is write-held, except that it is also read locklessly for
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diagnostic purposes. The code might look as follows:
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int foo;
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DEFINE_RWLOCK(foo_rwlock);
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void update_foo(int newval)
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{
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write_lock(&foo_rwlock);
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foo = newval;
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do_something(newval);
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write_unlock(&foo_rwlock);
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}
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int read_foo(void)
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{
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int ret;
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read_lock(&foo_rwlock);
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do_something_else();
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ret = foo;
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read_unlock(&foo_rwlock);
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return ret;
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}
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void read_foo_diagnostic(void)
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{
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pr_info("Current value of foo: %d\n", data_race(foo));
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}
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The reader-writer lock prevents the compiler from introducing concurrency
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bugs into any part of the main algorithm using foo, which means that
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the accesses to foo within both update_foo() and read_foo() can (and
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should) be plain C-language accesses. One benefit of making them be
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plain C-language accesses is that KCSAN can detect any erroneous lockless
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reads from or updates to foo. The data_race() in read_foo_diagnostic()
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tells KCSAN that data races are expected, and should be silently
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ignored. This data_race() also tells the human reading the code that
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read_foo_diagnostic() might sometimes return a bogus value.
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If it is necessary to suppress compiler optimization and also detect
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buggy lockless writes, read_foo_diagnostic() can be updated as follows:
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void read_foo_diagnostic(void)
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{
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pr_info("Current value of foo: %d\n", data_race(READ_ONCE(foo)));
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}
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Alternatively, given that KCSAN is to ignore all accesses in this function,
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this function can be marked __no_kcsan and the data_race() can be dropped:
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void __no_kcsan read_foo_diagnostic(void)
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{
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pr_info("Current value of foo: %d\n", READ_ONCE(foo));
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}
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However, in order for KCSAN to detect buggy lockless writes, your kernel
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must be built with CONFIG_KCSAN_ASSUME_PLAIN_WRITES_ATOMIC=n. If you
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need KCSAN to detect such a write even if that write did not change
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the value of foo, you also need CONFIG_KCSAN_REPORT_VALUE_CHANGE_ONLY=n.
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If you need KCSAN to detect such a write happening in an interrupt handler
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running on the same CPU doing the legitimate lock-protected write, you
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also need CONFIG_KCSAN_INTERRUPT_WATCHER=y. With some or all of these
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Kconfig options set properly, KCSAN can be quite helpful, although
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it is not necessarily a full replacement for hardware watchpoints.
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On the other hand, neither are hardware watchpoints a full replacement
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for KCSAN because it is not always easy to tell hardware watchpoint to
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conditionally trap on accesses.
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Lock-Protected Writes With Lockless Reads
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-----------------------------------------
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For another example, suppose a shared variable "foo" is updated only
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while holding a spinlock, but is read locklessly. The code might look
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as follows:
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int foo;
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DEFINE_SPINLOCK(foo_lock);
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void update_foo(int newval)
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{
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spin_lock(&foo_lock);
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WRITE_ONCE(foo, newval);
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ASSERT_EXCLUSIVE_WRITER(foo);
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do_something(newval);
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spin_unlock(&foo_wlock);
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}
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int read_foo(void)
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{
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do_something_else();
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return READ_ONCE(foo);
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}
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Because foo is read locklessly, all accesses are marked. The purpose
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of the ASSERT_EXCLUSIVE_WRITER() is to allow KCSAN to check for a buggy
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concurrent lockless write.
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Lock-Protected Writes With Heuristic Lockless Reads
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---------------------------------------------------
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For another example, suppose that the code can normally make use of
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a per-data-structure lock, but there are times when a global lock
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is required. These times are indicated via a global flag. The code
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might look as follows, and is based loosely on nf_conntrack_lock(),
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nf_conntrack_all_lock(), and nf_conntrack_all_unlock():
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bool global_flag;
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DEFINE_SPINLOCK(global_lock);
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struct foo {
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spinlock_t f_lock;
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int f_data;
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};
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/* All foo structures are in the following array. */
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int nfoo;
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struct foo *foo_array;
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void do_something_locked(struct foo *fp)
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{
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/* This works even if data_race() returns nonsense. */
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if (!data_race(global_flag)) {
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spin_lock(&fp->f_lock);
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if (!smp_load_acquire(&global_flag)) {
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do_something(fp);
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spin_unlock(&fp->f_lock);
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return;
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}
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spin_unlock(&fp->f_lock);
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}
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spin_lock(&global_lock);
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/* global_lock held, thus global flag cannot be set. */
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spin_lock(&fp->f_lock);
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spin_unlock(&global_lock);
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/*
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* global_flag might be set here, but begin_global()
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* will wait for ->f_lock to be released.
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*/
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do_something(fp);
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spin_unlock(&fp->f_lock);
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}
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void begin_global(void)
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{
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int i;
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spin_lock(&global_lock);
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WRITE_ONCE(global_flag, true);
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for (i = 0; i < nfoo; i++) {
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/*
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* Wait for pre-existing local locks. One at
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* a time to avoid lockdep limitations.
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*/
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spin_lock(&fp->f_lock);
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spin_unlock(&fp->f_lock);
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}
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}
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void end_global(void)
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{
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smp_store_release(&global_flag, false);
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spin_unlock(&global_lock);
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}
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All code paths leading from the do_something_locked() function's first
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read from global_flag acquire a lock, so endless load fusing cannot
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happen.
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If the value read from global_flag is true, then global_flag is
|
||
|
rechecked while holding ->f_lock, which, if global_flag is now false,
|
||
|
prevents begin_global() from completing. It is therefore safe to invoke
|
||
|
do_something().
|
||
|
|
||
|
Otherwise, if either value read from global_flag is true, then after
|
||
|
global_lock is acquired global_flag must be false. The acquisition of
|
||
|
->f_lock will prevent any call to begin_global() from returning, which
|
||
|
means that it is safe to release global_lock and invoke do_something().
|
||
|
|
||
|
For this to work, only those foo structures in foo_array[] may be passed
|
||
|
to do_something_locked(). The reason for this is that the synchronization
|
||
|
with begin_global() relies on momentarily holding the lock of each and
|
||
|
every foo structure.
|
||
|
|
||
|
The smp_load_acquire() and smp_store_release() are required because
|
||
|
changes to a foo structure between calls to begin_global() and
|
||
|
end_global() are carried out without holding that structure's ->f_lock.
|
||
|
The smp_load_acquire() and smp_store_release() ensure that the next
|
||
|
invocation of do_something() from do_something_locked() will see those
|
||
|
changes.
|
||
|
|
||
|
|
||
|
Lockless Reads and Writes
|
||
|
-------------------------
|
||
|
|
||
|
For another example, suppose a shared variable "foo" is both read and
|
||
|
updated locklessly. The code might look as follows:
|
||
|
|
||
|
int foo;
|
||
|
|
||
|
int update_foo(int newval)
|
||
|
{
|
||
|
int ret;
|
||
|
|
||
|
ret = xchg(&foo, newval);
|
||
|
do_something(newval);
|
||
|
return ret;
|
||
|
}
|
||
|
|
||
|
int read_foo(void)
|
||
|
{
|
||
|
do_something_else();
|
||
|
return READ_ONCE(foo);
|
||
|
}
|
||
|
|
||
|
Because foo is accessed locklessly, all accesses are marked. It does
|
||
|
not make sense to use ASSERT_EXCLUSIVE_WRITER() in this case because
|
||
|
there really can be concurrent lockless writers. KCSAN would
|
||
|
flag any concurrent plain C-language reads from foo, and given
|
||
|
CONFIG_KCSAN_ASSUME_PLAIN_WRITES_ATOMIC=n, also any concurrent plain
|
||
|
C-language writes to foo.
|
||
|
|
||
|
|
||
|
Lockless Reads and Writes, But With Single-Threaded Initialization
|
||
|
------------------------------------------------------------------
|
||
|
|
||
|
For yet another example, suppose that foo is initialized in a
|
||
|
single-threaded manner, but that a number of kthreads are then created
|
||
|
that locklessly and concurrently access foo. Some snippets of this code
|
||
|
might look as follows:
|
||
|
|
||
|
int foo;
|
||
|
|
||
|
void initialize_foo(int initval, int nkthreads)
|
||
|
{
|
||
|
int i;
|
||
|
|
||
|
foo = initval;
|
||
|
ASSERT_EXCLUSIVE_ACCESS(foo);
|
||
|
for (i = 0; i < nkthreads; i++)
|
||
|
kthread_run(access_foo_concurrently, ...);
|
||
|
}
|
||
|
|
||
|
/* Called from access_foo_concurrently(). */
|
||
|
int update_foo(int newval)
|
||
|
{
|
||
|
int ret;
|
||
|
|
||
|
ret = xchg(&foo, newval);
|
||
|
do_something(newval);
|
||
|
return ret;
|
||
|
}
|
||
|
|
||
|
/* Also called from access_foo_concurrently(). */
|
||
|
int read_foo(void)
|
||
|
{
|
||
|
do_something_else();
|
||
|
return READ_ONCE(foo);
|
||
|
}
|
||
|
|
||
|
The initialize_foo() uses a plain C-language write to foo because there
|
||
|
are not supposed to be concurrent accesses during initialization. The
|
||
|
ASSERT_EXCLUSIVE_ACCESS() allows KCSAN to flag buggy concurrent unmarked
|
||
|
reads, and the ASSERT_EXCLUSIVE_ACCESS() call further allows KCSAN to
|
||
|
flag buggy concurrent writes, even if: (1) Those writes are marked or
|
||
|
(2) The kernel was built with CONFIG_KCSAN_ASSUME_PLAIN_WRITES_ATOMIC=y.
|
||
|
|
||
|
|
||
|
Checking Stress-Test Race Coverage
|
||
|
----------------------------------
|
||
|
|
||
|
When designing stress tests it is important to ensure that race conditions
|
||
|
of interest really do occur. For example, consider the following code
|
||
|
fragment:
|
||
|
|
||
|
int foo;
|
||
|
|
||
|
int update_foo(int newval)
|
||
|
{
|
||
|
return xchg(&foo, newval);
|
||
|
}
|
||
|
|
||
|
int xor_shift_foo(int shift, int mask)
|
||
|
{
|
||
|
int old, new, newold;
|
||
|
|
||
|
newold = data_race(foo); /* Checked by cmpxchg(). */
|
||
|
do {
|
||
|
old = newold;
|
||
|
new = (old << shift) ^ mask;
|
||
|
newold = cmpxchg(&foo, old, new);
|
||
|
} while (newold != old);
|
||
|
return old;
|
||
|
}
|
||
|
|
||
|
int read_foo(void)
|
||
|
{
|
||
|
return READ_ONCE(foo);
|
||
|
}
|
||
|
|
||
|
If it is possible for update_foo(), xor_shift_foo(), and read_foo() to be
|
||
|
invoked concurrently, the stress test should force this concurrency to
|
||
|
actually happen. KCSAN can evaluate the stress test when the above code
|
||
|
is modified to read as follows:
|
||
|
|
||
|
int foo;
|
||
|
|
||
|
int update_foo(int newval)
|
||
|
{
|
||
|
ASSERT_EXCLUSIVE_ACCESS(foo);
|
||
|
return xchg(&foo, newval);
|
||
|
}
|
||
|
|
||
|
int xor_shift_foo(int shift, int mask)
|
||
|
{
|
||
|
int old, new, newold;
|
||
|
|
||
|
newold = data_race(foo); /* Checked by cmpxchg(). */
|
||
|
do {
|
||
|
old = newold;
|
||
|
new = (old << shift) ^ mask;
|
||
|
ASSERT_EXCLUSIVE_ACCESS(foo);
|
||
|
newold = cmpxchg(&foo, old, new);
|
||
|
} while (newold != old);
|
||
|
return old;
|
||
|
}
|
||
|
|
||
|
|
||
|
int read_foo(void)
|
||
|
{
|
||
|
ASSERT_EXCLUSIVE_ACCESS(foo);
|
||
|
return READ_ONCE(foo);
|
||
|
}
|
||
|
|
||
|
If a given stress-test run does not result in KCSAN complaints from
|
||
|
each possible pair of ASSERT_EXCLUSIVE_ACCESS() invocations, the
|
||
|
stress test needs improvement. If the stress test was to be evaluated
|
||
|
on a regular basis, it would be wise to place the above instances of
|
||
|
ASSERT_EXCLUSIVE_ACCESS() under #ifdef so that they did not result in
|
||
|
false positives when not evaluating the stress test.
|
||
|
|
||
|
|
||
|
REFERENCES
|
||
|
==========
|
||
|
|
||
|
[1] "Concurrency bugs should fear the big bad data-race detector (part 2)"
|
||
|
https://lwn.net/Articles/816854/
|
||
|
|
||
|
[2] "Who's afraid of a big bad optimizing compiler?"
|
||
|
https://lwn.net/Articles/793253/
|