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Document how KCSAN models a subset of weak memory and the subset of missing memory barriers it can detect as a result. Signed-off-by: Marco Elver <elver@google.com> Signed-off-by: Paul E. McKenney <paulmck@kernel.org>
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ReStructuredText
367 lines
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ReStructuredText
.. SPDX-License-Identifier: GPL-2.0
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.. Copyright (C) 2019, Google LLC.
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The Kernel Concurrency Sanitizer (KCSAN)
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========================================
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The Kernel Concurrency Sanitizer (KCSAN) is a dynamic race detector, which
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relies on compile-time instrumentation, and uses a watchpoint-based sampling
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approach to detect races. KCSAN's primary purpose is to detect `data races`_.
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Usage
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-----
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KCSAN is supported by both GCC and Clang. With GCC we require version 11 or
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later, and with Clang also require version 11 or later.
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To enable KCSAN configure the kernel with::
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CONFIG_KCSAN = y
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KCSAN provides several other configuration options to customize behaviour (see
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the respective help text in ``lib/Kconfig.kcsan`` for more info).
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Error reports
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~~~~~~~~~~~~~
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A typical data race report looks like this::
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==================================================================
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BUG: KCSAN: data-race in test_kernel_read / test_kernel_write
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write to 0xffffffffc009a628 of 8 bytes by task 487 on cpu 0:
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test_kernel_write+0x1d/0x30
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access_thread+0x89/0xd0
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kthread+0x23e/0x260
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ret_from_fork+0x22/0x30
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read to 0xffffffffc009a628 of 8 bytes by task 488 on cpu 6:
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test_kernel_read+0x10/0x20
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access_thread+0x89/0xd0
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kthread+0x23e/0x260
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ret_from_fork+0x22/0x30
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value changed: 0x00000000000009a6 -> 0x00000000000009b2
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Reported by Kernel Concurrency Sanitizer on:
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CPU: 6 PID: 488 Comm: access_thread Not tainted 5.12.0-rc2+ #1
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Hardware name: QEMU Standard PC (i440FX + PIIX, 1996), BIOS 1.14.0-2 04/01/2014
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==================================================================
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The header of the report provides a short summary of the functions involved in
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the race. It is followed by the access types and stack traces of the 2 threads
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involved in the data race. If KCSAN also observed a value change, the observed
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old value and new value are shown on the "value changed" line respectively.
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The other less common type of data race report looks like this::
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==================================================================
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BUG: KCSAN: data-race in test_kernel_rmw_array+0x71/0xd0
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race at unknown origin, with read to 0xffffffffc009bdb0 of 8 bytes by task 515 on cpu 2:
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test_kernel_rmw_array+0x71/0xd0
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access_thread+0x89/0xd0
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kthread+0x23e/0x260
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ret_from_fork+0x22/0x30
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value changed: 0x0000000000002328 -> 0x0000000000002329
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Reported by Kernel Concurrency Sanitizer on:
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CPU: 2 PID: 515 Comm: access_thread Not tainted 5.12.0-rc2+ #1
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Hardware name: QEMU Standard PC (i440FX + PIIX, 1996), BIOS 1.14.0-2 04/01/2014
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==================================================================
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This report is generated where it was not possible to determine the other
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racing thread, but a race was inferred due to the data value of the watched
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memory location having changed. These reports always show a "value changed"
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line. A common reason for reports of this type are missing instrumentation in
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the racing thread, but could also occur due to e.g. DMA accesses. Such reports
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are shown only if ``CONFIG_KCSAN_REPORT_RACE_UNKNOWN_ORIGIN=y``, which is
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enabled by default.
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Selective analysis
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~~~~~~~~~~~~~~~~~~
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It may be desirable to disable data race detection for specific accesses,
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functions, compilation units, or entire subsystems. For static blacklisting,
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the below options are available:
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* KCSAN understands the ``data_race(expr)`` annotation, which tells KCSAN that
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any data races due to accesses in ``expr`` should be ignored and resulting
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behaviour when encountering a data race is deemed safe. Please see
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`"Marking Shared-Memory Accesses" in the LKMM`_ for more information.
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* Disabling data race detection for entire functions can be accomplished by
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using the function attribute ``__no_kcsan``::
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__no_kcsan
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void foo(void) {
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...
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To dynamically limit for which functions to generate reports, see the
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`DebugFS interface`_ blacklist/whitelist feature.
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* To disable data race detection for a particular compilation unit, add to the
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``Makefile``::
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KCSAN_SANITIZE_file.o := n
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* To disable data race detection for all compilation units listed in a
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``Makefile``, add to the respective ``Makefile``::
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KCSAN_SANITIZE := n
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.. _"Marking Shared-Memory Accesses" in the LKMM: https://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git/tree/tools/memory-model/Documentation/access-marking.txt
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Furthermore, it is possible to tell KCSAN to show or hide entire classes of
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data races, depending on preferences. These can be changed via the following
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Kconfig options:
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* ``CONFIG_KCSAN_REPORT_VALUE_CHANGE_ONLY``: If enabled and a conflicting write
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is observed via a watchpoint, but the data value of the memory location was
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observed to remain unchanged, do not report the data race.
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* ``CONFIG_KCSAN_ASSUME_PLAIN_WRITES_ATOMIC``: Assume that plain aligned writes
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up to word size are atomic by default. Assumes that such writes are not
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subject to unsafe compiler optimizations resulting in data races. The option
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causes KCSAN to not report data races due to conflicts where the only plain
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accesses are aligned writes up to word size.
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* ``CONFIG_KCSAN_PERMISSIVE``: Enable additional permissive rules to ignore
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certain classes of common data races. Unlike the above, the rules are more
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complex involving value-change patterns, access type, and address. This
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option depends on ``CONFIG_KCSAN_REPORT_VALUE_CHANGE_ONLY=y``. For details
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please see the ``kernel/kcsan/permissive.h``. Testers and maintainers that
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only focus on reports from specific subsystems and not the whole kernel are
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recommended to disable this option.
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To use the strictest possible rules, select ``CONFIG_KCSAN_STRICT=y``, which
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configures KCSAN to follow the Linux-kernel memory consistency model (LKMM) as
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closely as possible.
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DebugFS interface
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~~~~~~~~~~~~~~~~~
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The file ``/sys/kernel/debug/kcsan`` provides the following interface:
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* Reading ``/sys/kernel/debug/kcsan`` returns various runtime statistics.
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* Writing ``on`` or ``off`` to ``/sys/kernel/debug/kcsan`` allows turning KCSAN
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on or off, respectively.
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* Writing ``!some_func_name`` to ``/sys/kernel/debug/kcsan`` adds
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``some_func_name`` to the report filter list, which (by default) blacklists
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reporting data races where either one of the top stackframes are a function
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in the list.
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* Writing either ``blacklist`` or ``whitelist`` to ``/sys/kernel/debug/kcsan``
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changes the report filtering behaviour. For example, the blacklist feature
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can be used to silence frequently occurring data races; the whitelist feature
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can help with reproduction and testing of fixes.
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Tuning performance
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~~~~~~~~~~~~~~~~~~
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Core parameters that affect KCSAN's overall performance and bug detection
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ability are exposed as kernel command-line arguments whose defaults can also be
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changed via the corresponding Kconfig options.
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* ``kcsan.skip_watch`` (``CONFIG_KCSAN_SKIP_WATCH``): Number of per-CPU memory
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operations to skip, before another watchpoint is set up. Setting up
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watchpoints more frequently will result in the likelihood of races to be
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observed to increase. This parameter has the most significant impact on
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overall system performance and race detection ability.
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* ``kcsan.udelay_task`` (``CONFIG_KCSAN_UDELAY_TASK``): For tasks, the
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microsecond delay to stall execution after a watchpoint has been set up.
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Larger values result in the window in which we may observe a race to
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increase.
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* ``kcsan.udelay_interrupt`` (``CONFIG_KCSAN_UDELAY_INTERRUPT``): For
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interrupts, the microsecond delay to stall execution after a watchpoint has
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been set up. Interrupts have tighter latency requirements, and their delay
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should generally be smaller than the one chosen for tasks.
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They may be tweaked at runtime via ``/sys/module/kcsan/parameters/``.
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Data Races
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----------
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In an execution, two memory accesses form a *data race* if they *conflict*,
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they happen concurrently in different threads, and at least one of them is a
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*plain access*; they *conflict* if both access the same memory location, and at
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least one is a write. For a more thorough discussion and definition, see `"Plain
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Accesses and Data Races" in the LKMM`_.
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.. _"Plain Accesses and Data Races" in the LKMM: https://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git/tree/tools/memory-model/Documentation/explanation.txt#n1922
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Relationship with the Linux-Kernel Memory Consistency Model (LKMM)
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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The LKMM defines the propagation and ordering rules of various memory
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operations, which gives developers the ability to reason about concurrent code.
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Ultimately this allows to determine the possible executions of concurrent code,
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and if that code is free from data races.
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KCSAN is aware of *marked atomic operations* (``READ_ONCE``, ``WRITE_ONCE``,
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``atomic_*``, etc.), and a subset of ordering guarantees implied by memory
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barriers. With ``CONFIG_KCSAN_WEAK_MEMORY=y``, KCSAN models load or store
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buffering, and can detect missing ``smp_mb()``, ``smp_wmb()``, ``smp_rmb()``,
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``smp_store_release()``, and all ``atomic_*`` operations with equivalent
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implied barriers.
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Note, KCSAN will not report all data races due to missing memory ordering,
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specifically where a memory barrier would be required to prohibit subsequent
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memory operation from reordering before the barrier. Developers should
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therefore carefully consider the required memory ordering requirements that
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remain unchecked.
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Race Detection Beyond Data Races
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--------------------------------
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For code with complex concurrency design, race-condition bugs may not always
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manifest as data races. Race conditions occur if concurrently executing
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operations result in unexpected system behaviour. On the other hand, data races
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are defined at the C-language level. The following macros can be used to check
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properties of concurrent code where bugs would not manifest as data races.
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.. kernel-doc:: include/linux/kcsan-checks.h
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:functions: ASSERT_EXCLUSIVE_WRITER ASSERT_EXCLUSIVE_WRITER_SCOPED
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ASSERT_EXCLUSIVE_ACCESS ASSERT_EXCLUSIVE_ACCESS_SCOPED
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ASSERT_EXCLUSIVE_BITS
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Implementation Details
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----------------------
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KCSAN relies on observing that two accesses happen concurrently. Crucially, we
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want to (a) increase the chances of observing races (especially for races that
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manifest rarely), and (b) be able to actually observe them. We can accomplish
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(a) by injecting various delays, and (b) by using address watchpoints (or
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breakpoints).
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If we deliberately stall a memory access, while we have a watchpoint for its
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address set up, and then observe the watchpoint to fire, two accesses to the
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same address just raced. Using hardware watchpoints, this is the approach taken
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in `DataCollider
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<http://usenix.org/legacy/events/osdi10/tech/full_papers/Erickson.pdf>`_.
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Unlike DataCollider, KCSAN does not use hardware watchpoints, but instead
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relies on compiler instrumentation and "soft watchpoints".
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In KCSAN, watchpoints are implemented using an efficient encoding that stores
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access type, size, and address in a long; the benefits of using "soft
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watchpoints" are portability and greater flexibility. KCSAN then relies on the
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compiler instrumenting plain accesses. For each instrumented plain access:
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1. Check if a matching watchpoint exists; if yes, and at least one access is a
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write, then we encountered a racing access.
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2. Periodically, if no matching watchpoint exists, set up a watchpoint and
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stall for a small randomized delay.
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3. Also check the data value before the delay, and re-check the data value
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after delay; if the values mismatch, we infer a race of unknown origin.
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To detect data races between plain and marked accesses, KCSAN also annotates
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marked accesses, but only to check if a watchpoint exists; i.e. KCSAN never
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sets up a watchpoint on marked accesses. By never setting up watchpoints for
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marked operations, if all accesses to a variable that is accessed concurrently
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are properly marked, KCSAN will never trigger a watchpoint and therefore never
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report the accesses.
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Modeling Weak Memory
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~~~~~~~~~~~~~~~~~~~~
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KCSAN's approach to detecting data races due to missing memory barriers is
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based on modeling access reordering (with ``CONFIG_KCSAN_WEAK_MEMORY=y``).
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Each plain memory access for which a watchpoint is set up, is also selected for
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simulated reordering within the scope of its function (at most 1 in-flight
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access).
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Once an access has been selected for reordering, it is checked along every
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other access until the end of the function scope. If an appropriate memory
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barrier is encountered, the access will no longer be considered for simulated
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reordering.
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When the result of a memory operation should be ordered by a barrier, KCSAN can
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then detect data races where the conflict only occurs as a result of a missing
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barrier. Consider the example::
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int x, flag;
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void T1(void)
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{
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x = 1; // data race!
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WRITE_ONCE(flag, 1); // correct: smp_store_release(&flag, 1)
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}
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void T2(void)
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{
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while (!READ_ONCE(flag)); // correct: smp_load_acquire(&flag)
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... = x; // data race!
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}
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When weak memory modeling is enabled, KCSAN can consider ``x`` in ``T1`` for
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simulated reordering. After the write of ``flag``, ``x`` is again checked for
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concurrent accesses: because ``T2`` is able to proceed after the write of
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``flag``, a data race is detected. With the correct barriers in place, ``x``
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would not be considered for reordering after the proper release of ``flag``,
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and no data race would be detected.
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Deliberate trade-offs in complexity but also practical limitations mean only a
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subset of data races due to missing memory barriers can be detected. With
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currently available compiler support, the implementation is limited to modeling
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the effects of "buffering" (delaying accesses), since the runtime cannot
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"prefetch" accesses. Also recall that watchpoints are only set up for plain
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accesses, and the only access type for which KCSAN simulates reordering. This
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means reordering of marked accesses is not modeled.
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A consequence of the above is that acquire operations do not require barrier
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instrumentation (no prefetching). Furthermore, marked accesses introducing
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address or control dependencies do not require special handling (the marked
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access cannot be reordered, later dependent accesses cannot be prefetched).
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Key Properties
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~~~~~~~~~~~~~~
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1. **Memory Overhead:** The overall memory overhead is only a few MiB
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depending on configuration. The current implementation uses a small array of
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longs to encode watchpoint information, which is negligible.
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2. **Performance Overhead:** KCSAN's runtime aims to be minimal, using an
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efficient watchpoint encoding that does not require acquiring any shared
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locks in the fast-path. For kernel boot on a system with 8 CPUs:
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- 5.0x slow-down with the default KCSAN config;
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- 2.8x slow-down from runtime fast-path overhead only (set very large
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``KCSAN_SKIP_WATCH`` and unset ``KCSAN_SKIP_WATCH_RANDOMIZE``).
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3. **Annotation Overheads:** Minimal annotations are required outside the KCSAN
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runtime. As a result, maintenance overheads are minimal as the kernel
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evolves.
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4. **Detects Racy Writes from Devices:** Due to checking data values upon
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setting up watchpoints, racy writes from devices can also be detected.
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5. **Memory Ordering:** KCSAN is aware of only a subset of LKMM ordering rules;
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this may result in missed data races (false negatives).
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6. **Analysis Accuracy:** For observed executions, due to using a sampling
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strategy, the analysis is *unsound* (false negatives possible), but aims to
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be complete (no false positives).
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Alternatives Considered
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-----------------------
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An alternative data race detection approach for the kernel can be found in the
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`Kernel Thread Sanitizer (KTSAN) <https://github.com/google/ktsan/wiki>`_.
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KTSAN is a happens-before data race detector, which explicitly establishes the
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happens-before order between memory operations, which can then be used to
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determine data races as defined in `Data Races`_.
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To build a correct happens-before relation, KTSAN must be aware of all ordering
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rules of the LKMM and synchronization primitives. Unfortunately, any omission
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leads to large numbers of false positives, which is especially detrimental in
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the context of the kernel which includes numerous custom synchronization
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mechanisms. To track the happens-before relation, KTSAN's implementation
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requires metadata for each memory location (shadow memory), which for each page
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corresponds to 4 pages of shadow memory, and can translate into overhead of
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tens of GiB on a large system.
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